James Dewar
Sir James Dewar FRS FRSE (20 September 1842 – 27 March 1923) was a British chemist and physicist. He is best known for his invention of the vacuum flask, which he used in conjunction with research into the liquefaction of gases. He also studied atomic and molecular spectroscopy, working in these fields for more than 25 years.
Sir James Dewar | |
---|---|
Born | Kincardine-on-Forth, Scotland | 20 September 1842
Died | 27 March 1923 80) London, England | (aged
Alma mater | University of Edinburgh |
Known for | |
Awards |
|
Scientific career | |
Fields | Physics, chemistry |
Institutions | |
Doctoral advisor | Lord Playfair |
Early life
James Dewar was born in Kincardine, Perthshire (now in Fife) in 1842, the youngest of six boys of Ann Dewar and Thomas Dewar, a vintner.[1] He was educated at Kincardine Parish School and then Dollar Academy. His parents died when he was 15. He attended the University of Edinburgh where he studied chemistry under Lyon Playfair (later Baron Playfair), becoming Playfair's personal assistant. Dewar also studied under August Kekulé at Ghent.
Career
In 1875, Dewar was elected Jacksonian professor of natural experimental philosophy at the University of Cambridge, becoming a member of Peterhouse.[2] He became a member of the Royal Institution and later, in 1877, replaced Dr John Hall Gladstone in the role of Fullerian Professor of Chemistry. Dewar was also the President of the Chemical Society in 1897 and the British Association for the Advancement of Science in 1902, as well as serving on the Royal Commission established to examine London's water supply from 1893 to 1894 and the Committee on Explosives. While serving on the Committee on Explosives, he and Frederick Augustus Abel developed cordite, a smokeless gunpowder alternative.
In 1867 Dewar described several chemical formulas for benzene, which were published in 1869.[3] One of the formulae, which does not represent benzene correctly and was not advocated by Dewar, is sometimes still called Dewar benzene.[4] In 1869 he was elected a Fellow of the Royal Society of Edinburgh, his proposer being his former mentor, Lyon Playfair.[1]
His scientific work covers a wide field – his earlier papers cover topics including organic chemistry, hydrogen and its physical constants, high-temperature research, the temperature of the Sun and of the electric spark, spectrophotometry, and the chemistry of the electric arc.
With Professor J. G. McKendrick, of the University of Glasgow, he investigated the physiological action of light and examined the changes that take place in the electrical condition of the retina under its influence. With Professor G. D. Liveing, one of his colleagues at the University of Cambridge, he began in 1878 a long series of spectroscopic observations, the later of which were devoted to the spectroscopic examination of various gaseous elements separated from atmospheric air by the aid of low temperatures. He was joined by Professor J. A. Fleming, of University College London, in the investigation of the electrical behaviour of substances cooled to very low temperatures.
His name is most widely known in connection with his work on the liquefaction of the so-called permanent gases and his researches at temperatures approaching absolute zero.[5] His interest in this branch of physics and chemistry dates back at least as far as 1874, when he discussed the "Latent Heat of Liquid Gases" before the British Association. In 1878, he devoted a Friday evening lecture at the Royal Institution to the then-recent work of Louis Paul Cailletet and Raoul Pictet, and exhibited for the first time in Great Britain the working of the Cailletet apparatus. Six years later, again at the Royal Institution, he described the researches of Zygmunt Florenty Wróblewski and Karol Olszewski, and illustrated for the first time in public the liquefaction of oxygen and air. Soon afterward, he built a machine from which the liquefied gas could be drawn off through a valve for use as a cooling agent, before using the liquid oxygen in research work related to meteorites; about the same time, he also obtained oxygen in the solid state.
By 1891, he had designed and built, at the Royal Institution, machinery which yielded liquid oxygen in industrial quantities, and towards the end of that year, he showed that both liquid oxygen and liquid ozone are strongly attracted by a magnet. About 1892, the idea occurred to him of using vacuum-jacketed vessels for the storage of liquid gases – the Dewar flask (otherwise known as a Thermos or vacuum flask) – the invention for which he became most famous. The vacuum flask was so efficient at keeping heat out, it was found possible to preserve the liquids for comparatively long periods, making an examination of their optical properties possible. Dewar did not profit from the widespread adoption of his vacuum flask – he lost a court case against Thermos concerning the patent for his invention. While Dewar was recognised as the inventor, because he did not patent his invention, there was no way to prevent Thermos from using his design.[6]
He next experimented with a high-pressure hydrogen jet by which low temperatures were realised through the Joule–Thomson effect, and the successful results he obtained led him to build at the Royal Institution a large regenerative cooling refrigerating machine. Using this machine in 1898, liquid hydrogen was collected for the first time, solid hydrogen following in 1899. He tried to liquefy the last remaining gas, helium, which condenses into a liquid at −268.9 °C, but owing to a number of factors, including a short supply of helium, Dewar was preceded by Heike Kamerlingh Onnes as the first person to produce liquid helium, in 1908. Onnes would later be awarded the Nobel Prize in Physics for his research into the properties of matter at low temperatures – Dewar was nominated several times, but never succeeded in winning the Nobel Prize.[6]
In 1905, he began to investigate the gas-absorbing powers of charcoal when cooled to low temperatures and applied his research to the creation of high vacuum, which was used for further experiments in atomic physics. Dewar continued his research work into the properties of elements at low temperatures, specifically low-temperature calorimetry, until the outbreak of World War I. The Royal Institution laboratories lost a number of staff to the war effort, both in fighting and scientific roles, and after the war, Dewar had little interest in restarting the serious research work that went on before the war. Shortages of scholars necessarily compounded the problems. His research during and after the war mainly involved investigating surface tension in soap bubbles, rather than further work into the properties of matter at low temperatures.
Family
He married Helen Rose Banks in 1871. They had no children. Helen was sister-in-law to both Charles Dickson, Lord Dickson and James Douglas Hamilton Dickson.[1]
Dewar's nephew, Dr Thomas William Dewar FRSE (1861–1931), was an amateur artist, who painted a portrait of Sir James Dewar.[7][8] He is presumably also the same Thomas William Dewar who was mentioned as executor in James Dewar's will, ultimately replaced "unopposed" by Dewar's wife.[9]
Royal Institution Christmas Lectures
Dewar was invited to deliver several Royal Institution Christmas Lectures:
- A Soap Bubble (1878)
- Atoms (1880)
- Alchemy in Relation to Modern Science (1883)
- The Story of a Meteorite (1885)
- The Chemistry of Light and Photography (1886)
- Clouds and Cloudland (1888)
- Frost and Fire (1890)
- Air: Gaseous and Liquid (1893)
- Christmas Lecture Epilogues (1912)
Honours and awards
Whilst Dewar was never recognised by the Swedish Academy, he was recognised by many other institutions both before and after his death, in Britain and overseas. The Royal Society elected him a Fellow of the Royal Society in June 1877 and bestowed their Rumford (1894), Davy (1909), and Copley Medal (1916) medals upon him for his work, as well as inviting him to deliver their Bakerian Lecture in 1901.[10] In 1899, he became the first recipient of the Hodgkins gold medal of the Smithsonian Institution, Washington, DC, for his contributions to knowledge of the nature and properties of atmospheric air.
He was President of the Society of Chemical Industry from 1887-88.[11]
In 1904, he was the first British subject to receive the Lavoisier Medal of the French Academy of Sciences, and in 1906, he was the first to be awarded the Matteucci Medal of the Italian Society of Sciences. He was knighted in 1904 and awarded the Gunning Victoria Jubilee Prize for 1900–1904 by the Royal Society of Edinburgh, and in 1908, he was awarded the Albert Medal of The Society of Arts. A lunar crater was named in his honour.
A street within the Kings Buildings complex of the University of Edinburgh was named in memory of Dewar in the early 21st century.
Later life
Dewar died on 27 March 1923 aged 80 and was cremated at Golders Green Crematorium in London. An urn with his ashes still resides there.[12]
Character
Dewar's irascibility was legendary. Rowlinson (2012) called him "ruthless", particularly with his colleague Siegfried Ruhemann.[13]
Selected publications
- George Downing Liveing; James Dewar (1915). Collected Papers on Spectroscopy. University press.
Collected Papers on Spectroscopy.
, G. D. Living and J. Dewar, Cambridge University Press, 1915
- Pippard, Brian. 1993. "Siegfried Ruhemann (1859-1943), F.R.S. 1914-1923." Notes and Records of the Royal Society of London 47 (2): 271–76.
- Rowlinson, Sir J. S. 2012. Sir James Dewar, 1842–1923: A Ruthless Chemist. Ashgate Publishing, Ltd.
See also
References
- C D Waterston; A Macmillan Shearer (July 2006). Former Fellows of The Royal Society of Edinburgh, 1783–2002: Part 1 (A–J) (PDF). Royal Society of Edinburgh. ISBN 090219884X. Archived from the original (PDF) on 24 January 2013. Retrieved 18 September 2015.
- "Dewar, James (DWR875J)". A Cambridge Alumni Database. University of Cambridge.
- Dewar, James (1869) "On the oxidation of phenyl alcohol, and a mechanical arrangement adapted to illustrate structure in the non-saturated hydrocarbons," Proceedings of the Royal Society of Edinburgh 6: 82–86.
- Baker and Rouvray, Journal of Chemical Education, 1978, vol. 55, p. 645.
- "ABSOLUTE ZERO - PBS NOVA DOCUMENTARY (full length)". YouTube. Archived from the original on 6 April 2017. Retrieved 23 November 2016.
- James, Frank. "Dewar, James". Chemistry Explained. Advameg Inc. Retrieved 22 May 2008.
- "Sir James Dewar (1842 – 1923) | Kincardine Local History Group".
- "Dr Thomas William Dewar (1861 - 1931) - Find A Grave Memorial". secure.findagrave.com. Retrieved 16 April 2018.
- Sir James Dewar 1842-1923: A Ruthless Chemist, by Sir J S Rawlinson.
- "Library and Archive Catalogue". Royal Society. Archived from the original on 27 February 2012. Retrieved 27 November 2010.
- https://www.soci.org/about-us/history/sci-presidents
- "Sir James Dewar (1842-1923)". Find a Grave. Retrieved 6 April 2022.
- Pippard 1993; Salzman 2000
- This article incorporates text from a publication now in the public domain: Chisholm, Hugh, ed. (1911). "Dewar, Sir James". Encyclopædia Britannica. Vol. 8 (11th ed.). Cambridge University Press. p. 137.
Further reading
- Armstrong, H. E.; Perkin, A. G.; Armstrong, Henry E. (1928). "Obituary of James Dewar". Journal of the Chemical Society: 1056–1076. doi:10.1039/JR9280001056. Retrieved 30 August 2008.
- Bellis, Mary, "Inventors Sir James Dewar" from about.com
- Meiklejohn, William, "Tulliallan: Four lads o' pairts: Sir James Dewar (1842–1923)" from the Kincardine Local History Group
- Sella, Andrea (August 2008). "Dewar's Flask". Chemistry World: 75. Retrieved 30 August 2008.
- Sloane, Thomas O'Conor (1900). Liquid Air, and the Liquefaction of Gases. Henley., Liquid Air and the Liquefaction of Gases, Norman W. Henley and Co., New York, 1900, second edition (extensive description of Dewar's work on the liqufaction of gases)
External links
- Fullerian Professorships
- Brief biography from the Royal Institution of Great Britain
- Another brief biography
- "Archival material relating to James Dewar". UK National Archives.
- Correspondence with H.A. Kamerlingh Onnes, Dewar's competitor in the race to liquid helium.